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I regularly find rolling things of time series (particularly means), and was surprised to find that rollmean is notably faster than rollapply, and that the align = 'right' methods are faster than the rollmeanr wrappers.

How have they achieved this speed up? And why does one lose some of it when using the rollmeanr() wrapper?

Some background: I had been using rollapplyr(x, n, function(X) mean(X)), however I recently happened upon a few examples using rollmean. The documents suggest rollapplyr(x, n, mean) (note without the function part of the argument) uses rollmean so I didn't think that there would be much difference in performance, however rbenchmark revealed notable differences.

require(zoo)
require(rbenchmark)

x <- rnorm(1e4)
r1 <- function() rollapplyr(x, 3, mean) # uses rollmean
r2 <- function() rollapplyr(x, 3, function(x) mean(x))
r3 <- function() rollmean(x, 3, na.pad = TRUE, align = 'right')
r4 <- function() rollmeanr(x, 3, align = "right")

bb <- benchmark(r1(), r2(), r3(), r4(), 
          columns = c('test', 'elapsed', 'relative'), 
          replications = 100, 
          order = 'elapsed')

print(bb)

I was surprised to find that rollmean(x, n, align = 'right') was notably faster -- and ~40x faster than my rollapply(x, n, function(X) mean(X)) approach.

  test elapsed relative
3 r3()    0.74    1.000
4 r4()    0.86    1.162
1 r1()    0.98    1.324
2 r2()   27.53   37.203

The difference seems to get larger as the size of the data-set grows. I changed only the size of x (to rnorm(1e5)) in the above code and re-ran the test and there was an even larger difference between the functions.

  test elapsed relative
3 r3()   13.33    1.000
4 r4()   17.43    1.308
1 r1()   19.83    1.488
2 r2()  279.47   20.965 

and for x <- rnorm(1e6)

  test elapsed relative
3 r3()   44.23    1.000
4 r4()   54.30    1.228
1 r1()   65.30    1.476
2 r2() 2473.35   55.920

How have they done this? Also, is this the optimal solution? Sure, this is fast but is there an even faster way to do this?

(Note: in general my time series are almost always xts objects -- does this matter?)

share|improve this question
2  
you may want to try runmean from caTools for much faster results – eddi Aug 7 '13 at 20:44
2  
@DWIN i did read the help page. I saw the text you quoted in ?rollapplyr but it doesn't explain why. Next i went to ?rollmean and found "These functions compute rolling means, maximums and medians respectively and are thus similar to ‘rollapply’ but are optimized for speed" ... which doesn't explain why either. Additionally, neither explains why rollmean(x, n, align = 'right') is faster than rollmeanr(x, n). Finally, none of this explains why performance gaps grow with the size of the data. – ricardo Aug 7 '13 at 20:49
1  
@DWin -- this is a code exchange, so i expected the answer would be that XYZ has been done to speed rollmean up, that rollmean(x, n, align = 'right') is faster than rollmeanr for some good reason, and that the performance gaps grow as task size grows for some other interesting reason. Isn't this place here to help folks learn? – ricardo Aug 7 '13 at 20:58
2  
To start with, I'd suggest to just have a peek at the functions by doing getAnywhere("rollmean.zoo") and getAnywhere("rollapply.zoo"). – Arun Aug 7 '13 at 21:11
4  
I'd be really surprised if someone didn't know what OP meant because he said "Why" instead of "How" – Señor O Aug 7 '13 at 21:39
up vote 7 down vote accepted

Computing the rolling mean is faster than computing a general rolling function, because the first one is easier to compute. When computing a general rolling function you have to compute the function on each window again and again, which you don't have to do for mean, because of the simple identity:

 (a2 + a3 + ... + an)/(n-1) = (a1 + a2 + ... + a(n-1))/(n-1) + (an - a1)/(n-1)

and you can see how that's leveraged by looking at getAnywhere(rollmean.zoo).

If you want an even faster rolling mean, use runmean from caTools, which is implemented in C making it much faster (it also scales a lot better so will get even faster as the size of data increases).

library(microbenchmark)
library(caTools)
library(zoo)

x = rnorm(1e4)
microbenchmark(runmean(x, 3, endrule = 'trim', align = 'right'),
               rollmean(x, 3, align = 'right'))
#Unit: microseconds
#                                             expr      min        lq     median        uq       max neval
# runmean(x, 3, endrule = "trim", align = "right")  631.061  740.0775   847.5915  1020.048  1652.109   100
#                  rollmean(x, 3, align = "right") 7308.947 9155.7155 10627.0210 12760.439 16919.092   100
share|improve this answer
    
There's also TTR::runMean, which works well with xts objects. – Joshua Ulrich Aug 8 '13 at 15:25

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